A fully coupled three-dimensional hydro-mechanical finite discrete element approach with real porous seepage for simulating 3D hydraulic fracturing

A fully coupled three-dimensional hydro-mechanical finite discrete element approach with real porous seepage for simulating 3D hydraulic fracturing

A fully coupled 3D hydro-mechanical model with real porous seepage is presented for simulating hydraulic fracturing. In this model, fluid flow in a fracture is expressed by 2D fracture seepage in the broken joint elements based on the Cubic law, while fluid flow in the rock matrix is represented by...

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Veröffentlicht in:Computers and geotechnics 2018-04, Vol.96, p.73-89
Hauptverfasser: Yan, Chengzeng, Jiao, Yu-Yong, Zheng, Hong
Format: Artikel
Sprache:eng
Schlagworte:
3-D technology
3D finite discrete element method (FDEM3D)
Computational fluid dynamics
Computer simulation
Crack initiation
Crack propagation
Darcys law
Discrete element method
Fluid flow
Fluid pressure
Fracture seepage
Hydraulic fracturing
Hydro-mechanical coupling
Hydrocarbon leakage & seepage
Mechanical properties
Porous seepage
Rock deformation
Rock fracture
Seepage
Solutions
Three dimensional models
Two dimensional models
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Zusammenfassung:A fully coupled 3D hydro-mechanical model with real porous seepage is presented for simulating hydraulic fracturing. In this model, fluid flow in a fracture is expressed by 2D fracture seepage in the broken joint elements based on the Cubic law, while fluid flow in the rock matrix is represented by 3D porous seepage in the tetrahedral elements based on Darcy's law. Several problems that have closed-form solutions and a 3D fracturing problem are given to verify the model. The simulation results show that the model can capture crack initiation and propagation, and the fluid pressure evolution during hydraulic fracturing.
ISSN:0266-352X
1873-7633
DOI:10.1016/j.compgeo.2017.10.008